EP1607028B1 - Load bearing surface - Google Patents

Load bearing surface Download PDF

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Publication number
EP1607028B1
EP1607028B1 EP05012021A EP05012021A EP1607028B1 EP 1607028 B1 EP1607028 B1 EP 1607028B1 EP 05012021 A EP05012021 A EP 05012021A EP 05012021 A EP05012021 A EP 05012021A EP 1607028 B1 EP1607028 B1 EP 1607028B1
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EP
European Patent Office
Prior art keywords
membrane
elastomeric
load bearing
elastomeric membrane
bearing surface
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
EP05012021A
Other languages
German (de)
French (fr)
Other versions
EP1607028A3 (en
EP1607028A2 (en
Inventor
Timothy P. Coffield
Daniel S. Sommerfield
Joseph D. Ward
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Illinois Tool Works Inc
Original Assignee
Illinois Tool Works Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Illinois Tool Works Inc filed Critical Illinois Tool Works Inc
Priority to EP10167976A priority Critical patent/EP2238868B1/en
Publication of EP1607028A2 publication Critical patent/EP1607028A2/en
Publication of EP1607028A3 publication Critical patent/EP1607028A3/en
Application granted granted Critical
Publication of EP1607028B1 publication Critical patent/EP1607028B1/en
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Anticipated expiration legal-status Critical

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Classifications

    • AHUMAN NECESSITIES
    • A47FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
    • A47CCHAIRS; SOFAS; BEDS
    • A47C5/00Chairs of special materials
    • A47C5/12Chairs of special materials of plastics, with or without reinforcement
    • AHUMAN NECESSITIES
    • A47FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
    • A47CCHAIRS; SOFAS; BEDS
    • A47C7/00Parts, details, or accessories of chairs or stools
    • A47C7/02Seat parts
    • A47C7/14Seat parts of adjustable shape; elastically mounted ; adaptable to a user contour or ergonomic seating positions
    • AHUMAN NECESSITIES
    • A47FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
    • A47CCHAIRS; SOFAS; BEDS
    • A47C7/00Parts, details, or accessories of chairs or stools
    • A47C7/02Seat parts
    • A47C7/14Seat parts of adjustable shape; elastically mounted ; adaptable to a user contour or ergonomic seating positions
    • A47C7/144Seat parts of adjustable shape; elastically mounted ; adaptable to a user contour or ergonomic seating positions with array of movable supports
    • AHUMAN NECESSITIES
    • A47FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
    • A47CCHAIRS; SOFAS; BEDS
    • A47C7/00Parts, details, or accessories of chairs or stools
    • A47C7/02Seat parts
    • A47C7/28Seat parts with tensioned springs, e.g. of flat type
    • A47C7/282Seat parts with tensioned springs, e.g. of flat type with mesh-like supports, e.g. elastomeric membranes
    • AHUMAN NECESSITIES
    • A47FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
    • A47CCHAIRS; SOFAS; BEDS
    • A47C7/00Parts, details, or accessories of chairs or stools
    • A47C7/02Seat parts
    • A47C7/28Seat parts with tensioned springs, e.g. of flat type
    • A47C7/287Seat parts with tensioned springs, e.g. of flat type with combinations of different types flat type tensioned springs
    • AHUMAN NECESSITIES
    • A47FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
    • A47CCHAIRS; SOFAS; BEDS
    • A47C7/00Parts, details, or accessories of chairs or stools
    • A47C7/62Accessories for chairs
    • A47C7/72Adaptations for incorporating lamps, radio sets, bars, telephones, ventilation, heating or cooling arrangements or the like
    • A47C7/74Adaptations for incorporating lamps, radio sets, bars, telephones, ventilation, heating or cooling arrangements or the like for ventilation, heating or cooling
    • A47C7/742Adaptations for incorporating lamps, radio sets, bars, telephones, ventilation, heating or cooling arrangements or the like for ventilation, heating or cooling for ventilating or cooling
    • A47C7/746Adaptations for incorporating lamps, radio sets, bars, telephones, ventilation, heating or cooling arrangements or the like for ventilation, heating or cooling for ventilating or cooling without active means, e.g. with openings or heat conductors
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C55/00Shaping by stretching, e.g. drawing through a die; Apparatus therefor
    • B29C55/02Shaping by stretching, e.g. drawing through a die; Apparatus therefor of plates or sheets
    • B29C55/10Shaping by stretching, e.g. drawing through a die; Apparatus therefor of plates or sheets multiaxial
    • B29C55/12Shaping by stretching, e.g. drawing through a die; Apparatus therefor of plates or sheets multiaxial biaxial
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29DPRODUCING PARTICULAR ARTICLES FROM PLASTICS OR FROM SUBSTANCES IN A PLASTIC STATE
    • B29D7/00Producing flat articles, e.g. films or sheets
    • B29D7/01Films or sheets
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16FSPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
    • F16F1/00Springs
    • F16F1/36Springs made of rubber or other material having high internal friction, e.g. thermoplastic elastomers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16FSPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
    • F16F2226/00Manufacturing; Treatments
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T428/00Stock material or miscellaneous articles
    • Y10T428/24Structurally defined web or sheet [e.g., overall dimension, etc.]
    • Y10T428/24628Nonplanar uniform thickness material
    • Y10T428/24669Aligned or parallel nonplanarities
    • Y10T428/24694Parallel corrugations
    • Y10T428/24711Plural corrugated components
    • Y10T428/24719Plural corrugated components with corrugations of respective components intersecting in plane projection
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T428/00Stock material or miscellaneous articles
    • Y10T428/24Structurally defined web or sheet [e.g., overall dimension, etc.]
    • Y10T428/24942Structurally defined web or sheet [e.g., overall dimension, etc.] including components having same physical characteristic in differing degree
    • Y10T428/2495Thickness [relative or absolute]
    • Y10T428/24967Absolute thicknesses specified
    • Y10T428/24975No layer or component greater than 5 mils thick

Definitions

  • the present invention relates to load bearing surfaces, and more particularly to elastomeric load bearing surfaces, such as the seat or back of a chair or bench, or the support surface of a bed, cot or other similar product.
  • the invention relates to a load bearing surface according to the preamble of claim 1 and to a method for manufacturing a load bearing surface according to the preamble of claim 11.
  • a load bearing surface and a method of this kind are known from US 4,399,574 .
  • GB 2 088 206 A relates to ventilative bedding comprising a plurality of wire coils.
  • molded load bearing surfaces for a wide variety of applications.
  • molded plastic chairs e.g. lawn chairs
  • these molded chairs provide an inexpensive seating option, they do not provide the level of support and comfort available in more expensive load bearing surfaces, such as conventional cushion sets. Rather, they provide an essentially linear force/deflection profile, which gives the typical molded seating surfaces the feel of a drum or a trampoline. In seating and other body-support applications, this may result in an uncomfortable and sometimes ergonomically unacceptable load bearing surface.
  • the ability to tune the characteristics of a conventional molded seat is relatively limited. Different materials and different material thicknesses can be used to provide a limited degree of control over the characteristics of the seat, but this level of control is not sufficient in many applications.
  • Elastomeric fabrics can provide a comfortable, ventilated seating structure.
  • Elastomeric fabrics are typically manufactured from a complex weave of high tech elastomeric monofilaments and multifilament yarns. The process results in a relatively expensive surface.
  • elastomeric fabric surfaces can be quite comfortable in many applications, they typically deflect like a sling when a load is applied. Some ergonomic specialists refer to this type of deflection as "hammocking" and consider it undesirable because it can cause the hips to rotate upward.
  • hammocking To minimize hammocking, many suspension seats are stretched quite tightly to reduce the amount of deflection that occurs under load. This can reduce the cushion-like feel of the seat making it feel more like a tightly stretched drum.
  • elastomeric fabrics may not be ideal in all applications.
  • the present invention provides an elastomeric load bearing surface having different support characteristics in different directions.
  • the support characteristics are varied (or decoupled) in directions that are perpendicular to one another.
  • the load bearing surface includes a molded elastomeric membrane that is decoupled by affecting the orientation of the structure of the membrane on a molecular level.
  • the molded elastomeric membrane may be oriented by compressing or stretching the membrane in one direction to the extent necessary to increase the alignment of the crystallize structure of the elastomer.
  • the orientation process varies the support characteristics of the membrane resulting in a membrane with significant elasticity in the direction of orientation and a low level of creep. The orientation process leaves the membrane with minimal elasticity in the direction perpendicular to the oriented direction.
  • the molded elastomeric membrane includes mechanical structure that affects the support and load bearing characteristics of the membrane.
  • the membrane may include without limitation slits, channels, undulations or other integral elements that provide "slack" in one direction. If desired, the membrane may be oriented and include mechanical decoupling structure.
  • the membrane is segregated into a plurality of nodes that provide a degree of independence from one location on the membrane to another.
  • the membrane defines a plurality of interconnected geometric shapes.
  • the membrane may include a plurality of square or triangular nodes that are interconnected by integral connector segments.
  • the characteristics of the connector segments may be varied to control the support characteristics of the membrane.
  • the membrane may include non-planar connector segments that can flex or otherwise deform under load to provide the membrane with "slack.”
  • the present invention also provides a method of manufacturing a load bearing surface from an elastomeric material.
  • the method generally includes the steps of (a) molding an elastomeric membrane and (b) orienting the elastomeric membrane in one direction by stretching the elastomeric membrane in that direction or by compressing the elastomeric membrane in such a way as to cause it to flow in that direction.
  • the elastomeric membrane is stretched or compressed to a point where there is an increase in the alignment of the crystalline structure of the elastomeric material in the oriented direction.
  • the method further includes the step of molding the elastomeric membrane with a structure that mechanically decouples the membrane in a direction different from that in which the membrane is oriented. This decoupled direction may be perpendicular to the oriented direction.
  • the membrane is compressed by the steps of (a) constraining the membrane on all sides except those sides corresponding with the desired direction of orientation and (b) applying a compression force to the membrane such that the material of the membrane flows in the unconstrained direction to increase the alignment of the crystalline structure of the membrane in the direction of flow.
  • the present invention provides a strong, yet flexible load bearing surface.
  • the elastomeric load bearing surfaces are relatively inexpensive to manufacture, and provide a light weight surface that can be ventilated to inhibit heat retention.
  • the decoupled elastomeric material exhibits support characteristics that are particularly well suited for use in seating applications because it provides different degrees of elasticity and support in different directions.
  • the decoupled elastomeric material can provide a seating structure with elasticity in the left to right direction, but not in the front to back direction. Further, by increasing the alignment of the crystalline structure of the elastomeric material, the level of creep in the membrane can be dramatically reduced.
  • a load bearing surface 10 according to one embodiment of the present invention is shown in Fig. 1 .
  • the load bearing surface 10 shown in Fig. 1 is a molded membrane that may be suspended from a support structure, such a chair seat frame (not shown).
  • the load bearing surface 10 includes support characteristics that differ in different directions. For example, the load bearing surface may provide significant elastic support in the x direction while providing relatively little support in the y direction. This "decoupling" of the support characteristics of the load bearing surface provides a high degree of comfort.
  • the present invention is described in connection with various alternative embodiments intended primarily for use in seating applications. The present invention is not, however, limited to use in seating applications, but may also be incorporated into other load bearing applications.
  • the support characteristics of the molded membrane are highly adjustable, thereby permitting the load bearing surface 10 to be tailored to support a variety of loads in a variety of different applications.
  • the load bearing surface 10 includes a molded elastomeric membrane 12.
  • the membrane 12 is molded from a thermoplastic polyether ester elastomer block copolymer.
  • a suitable material of this type is available from DuPont under the Hytrel ® trademark.
  • a variety of alternative elastomers may be suitable for use in the present invention.
  • the thickness of the molded membrane 12 will vary from application to application depending primarily on the anticipated load, but the support portion of the membrane may have an average thickness prior to any desired orienting of approximately 20-40 mm in standard seating applications.
  • the molded membrane 12 is oriented in one direction (i.e. the x direction) to provide creep resistance and elasticity in the direction of orientation.
  • the membrane 12 is oriented by increasing the alignment of the crystalline structure of the elastomeric membrane on a molecular level so that its support and other load bearing characteristics are altered.
  • the membrane with be oriented to such a degree that the oriented membrane 12 has materially different load bearing characteristics in the oriented direction than in other directions.
  • One method for orienting the membrane 12 is through stretching. The amount of stretch required to obtain the desired alignment will vary from application to application, but in most applications the desired degree of alignment will occur when the membrane is stretched to roughly two times its original dimension.
  • the elastomeric membrane 12 may be oriented by stretching the membrane, it may be possible in some application to orient the membrane 12 using other processes.
  • elastomeric materials including molded Hytrel®, have essentially no elasticity and are susceptible to a high degree of creep when in a molded form.
  • the orientation process of the present invention causes a significant change in the properties of the elastomeric material.
  • orientation of the membrane 12 increases the elasticity of the material and decreases its inherent susceptibility to creep.
  • the elastomeric membrane 12 of Fig. 1 also includes a plurality of undulations 14 that provide "slack" in the direction perpendicular to the direction of orientation (i.e. the y direction). When a load is applied to the membrane 12, the undulations 14 can undergo a "flattening" that permits the membrane 12 to expand in the y direction.
  • the undulations 14 and other mechanical decoupling structures are described in more detail below.
  • the membrane 12 of Fig. 1 also includes an integral edge 16 that may be mounted directly to the desired support structure (not shown), such as the seat frame of a chair.
  • the edge 16 extends around the periphery of the membrane 12 and is significantly thicker than the remainder of the membrane 12.
  • the edge 16 may include integral snap or other attachment features (not shown) that facilitate attachment of the membrane 12 to the support structure.
  • the edge 16 may be attached using fasteners (not shown), such as screws or bolts.
  • the edge 16 does not necessarily extend entirely around the membrane 12, but may instead include one or more segments located at different locations around the periphery. For example, an edge segment may be located in each corner of a rectangular membrane (not shown).
  • the edge 16 is also not necessarily located on the periphery of the membrane 12.
  • Figs. 8A-C Three alternative edge constructions are shown in Figs. 8A-C.
  • Fig. 8A shows an edge 16' having holes 17' to facilitate attachment of the edge 16' to a support structure (not shown).
  • fasteners may pass through the holes 17'.
  • the holes 17' may be fitted over attachment structure on the support structure (not shown), such as post.
  • Fig. 8B shows an edge 16" that is substantially circular in cross section.
  • Fig. 8C shows an edge 16''' that is substantially square in cross section.
  • the elastomeric membrane 12 is molded using conventional techniques and apparatus.
  • the elastomeric membrane 12 may be injection molded using a conventional injection molding apparatus (not shown) having a die that is configured to provide a membrane with the desired shape and features.
  • the elastomeric membrane 12 is manufactured by injecting the desired material into the die cavity.
  • the die is designed to provide a molded blank (See Fig. 3A ) that will take on the desired shape once any desired orientation have taken place.
  • the dies are configured to form a part that will have the desired shape and dimensions after the orientation step is complete.
  • the molded membrane may be stretched or otherwise oriented in one direction (See Fig. 3B ).
  • the precise amount of stretch to be applied to a given membrane will depend on the configuration of the membrane and the desired support characteristics. In many applications, it will be necessary to stretch the membrane to at least twice it original length to achieve the desired alignment.
  • the membrane may be stretched using conventional techniques and apparatus. As a result of the increase in alignment of the crystalline structure, the membrane 12 will not fully return to its original length after being released from the stretching equipment. Rather, the oriented membrane 12 will be elongated a certain portion of the stretched distance, with the precise amount of elongation being dependent in large part on the material characteristics of the membrane material (See Fig. 3C ). Once any desired orientation has taken place, the membrane 12 can be mounted directly to the support structure using essentially any mounting technique.
  • the edge 16 of the membrane can be fastened to a support structure by screws or other fasteners.
  • the membrane 12 may be oriented by compression.
  • the membrane 12 is placed in a die or other structure (not shown) that constrains the membrane 12 on all sides other than at least one side that corresponds with the desired direction of orientation. Opposed sides may be unconstrained to permit the material of the membrane 12 to flow from both sides along the direction of orientation. Alternatively, only a single side may be unconstrained, thereby limiting material flow to a single side.
  • a compressive force is then applied to the membrane 12.
  • a press can be used to compress the membrane 12 within the die.
  • Sufficient compressive force is applied so that the material begins to flow in the unconstrained direction. This in effect causes the membrane 12 to extend and its crystalline structure to become increasingly aligned in the direction of orientation.
  • the amount of force applied to the membrane 12 may vary from application depending on the desired degree of alignment or orientation. Although described in connection with orientation of the entire elastomeric membrane 12, in some application it is not necessary to orient the entire membrane 12. Rather, in some application, it may be desirable to orient only select portions of the membrane. For example, in some applications it may be desirable to orient only select peripheral portions of the membrane. When desirable, this may be achieved by applying localized stretching or localized compression of the membrane.
  • a molded membrane in the present invention provides the ability to easily create textures on the membrane, provide the membrane with essentially any desired contour and vary the thickness of the membrane in different locations.
  • the upper surface of the membrane may be smooth or may be textured to provide the appearance of leather, fabric or other desired textures.
  • the upper surface of the membrane may be provided with essentially any conceivable design elements (not shown), such as tiny bumps, corrugations, perforations or a spider web pattern.
  • contours and varying thicknesses across the membrane 12 permits localized control over the support characteristics of the membrane 12. For example, the membrane 12 may be thicker in regions where increased support is desired.
  • the elastomeric membrane may be oriented in one direction to reduce creep and provide the membrane with a desired level of elasticity in the direction of orientation.
  • the membrane 12' defines a plurality of slits or apertures that decouple the stiffness of the membrane in the x and y directions. More specifically, the membrane 12' defines a plurality of apertures 26' that permit a specific amount of extension of the membrane in the desired direction (i.e. the y direction) without significant stretching of the membrane 12'.
  • the apertures 26' may be elongated as shown in Fig. 5A . As shown, the apertures 26' may by staggered across the surface of the membrane 12' with the precise shape, number, location and size of the apertures 26' being dictated primarily by the desired support characteristics.
  • the membrane 12' may be molded with a bead 27' around each aperture 26' to reduce the possibility of tearing. As noted above, the membrane 12' may be oriented in the x direction as described above in connection with membrane 12.
  • the membrane 12" includes undulating variations 26" that decouple the stiffness of the membrane 12" by providing "slack" in one direction (e.g. the y direction).
  • the undulating variations 26" may be sinusoidal when viewed in cross-section.
  • the undulating variations 26" may resemble an accordion or pleated configuration when view in cross-section.
  • the undulations may follow essentially any contour that varies in the z direction.
  • the undulations 26" are arranged parallel to one another. As a result, the undulations 26" cooperate to provide slack in essentially one direction.
  • the undulations 26" may, however, be in a non-parallel arrangement when appropriate to provide the desired support characteristics.
  • the number, size, shape and location of the undulations 26" can be tuned to provide control over the support characteristics of the membrane 12".
  • the membrane 10''' includes a plurality of ribs 26''' extending at least partially across the membrane 12"'.
  • the membrane 12"' includes a plurality of parallel ribs 26'''.
  • the ribs 26"' provide the membrane 12''' with additional material that reduces the force required to stretch the membrane 12''' in the direction perpendicular to the ribs 26"' (i.e. the y direction), while at the same time having little effect on the force required to stretch the membrane 12'''' in the direction parallel to the ribs (i.e. the x direction).
  • the number, size, shape and location of the ribs 26''' can be tuned to provide control over the support characteristics of the membrane 12"'.
  • the load bearing surface may optionally be divided into a plurality of nodes.
  • the molded elastomeric membrane 112 shown in Figs. 2A-B includes a plurality nodes 118 interconnected by a plurality of connector segments 120, 122. As perhaps best shown in Fig. 2B , the nodes 118 and connector segments 120, 122 are integrally formed as a single molded part. In the embodiment of Figs. 2A-B , the membrane 112 includes a plurality of substantially square, equal-sized, regularly-spaced nodes 118. The nodes 118 need not, however, be of equal-size or be regularly-spaced.
  • the nodes 118 may vary in size, shape, spacing or other characteristics in different regions of the membrane 112 to provide localized control over the support characteristics of the membrane 112 in the different regions.
  • the nodes 118 of this embodiment are substantially square, they may vary in shape from application to application. For example, circular, triangular, rectangular or irregular shapes nodes may be desired in certain applications.
  • the illustrated nodes 118 have a generally planar upper surface 124, but the upper surface 124 may be contoured.
  • the nodes 118 may have a convex upper surface (not shown).
  • the spaces 126 defined between the nodes 118 and the connector segments 120, 122 provide a ventilated membrane 112. The size, shape and configuration of the spaces 126 can be tailored to provide the desired balance between ventilation and support characteristics.
  • the nodes 118 are interconnected by a plurality of connector segments 120, 122 (See Fig. 2B ).
  • the support characteristics of the membrane 112 are affected by the number, size, shape and other characteristics of the connector segments 120, 122.
  • the membrane 110 configured to provide elastic support along one direction.
  • the connector segments 120 joining the nodes 118 in the oriented direction x are substantially planar.
  • the elastomeric membrane 112 undergoes a stretching action in the direction of orientation when a load is applied.
  • the membrane 112 is configured to have minimal elastic response in the y direction (i.e. the direction perpendicular to the oriented direction).
  • the connector segments 122 joining the nodes 118 in the y direction are generally non-planar following a somewhat U-shaped arc.
  • the connector segments 122 provide the membrane with "slack" in the direction perpendicular to the oriented direction.
  • the non-planar connectors 122 undergo a bending action that essentially flats the connectors taking the "slack" out of the membrane 112. This permits the membrane 112 to undergo a certain amount of expansion in the direction of the slack without stretching of the membrane 112.
  • the amount of load required to achieve this expansion can be built into the membrane 112 by tuning the design and configuration of the connector segments 120, 122.
  • the bending action generally provides significantly less resistance to the expansion of the membrane 112 and less elastic return than would normally result from a stretching action.
  • the membrane 112 provides elastic support primarily in the direction of orientation.
  • the load bearing surface 200 includes an upper layer 204 having a plurality of loosely connected nodes 208, a lower layer 206 that interfaces with and supports the upper layer 204 and a plurality of spring elements 250 interposed between the upper layer 204 and the lower layer 206.
  • the upper layer 204 includes a plurality of interconnected nodes 208.
  • the upper layer 204 may be a single molded sheet formed with integral connector segments 212 that interconnect adjacent nodes 208.
  • the nodes 208 are square. But, the nodes 208 may be of other shapes. For example, in the alternative embodiment of Figs. 16-17 , the nodes 208' are triangular.
  • the characteristics of the connector segments 212 are selected to provide the desired level of interdependence between adjacent nodes 208. For example, relatively short, thick connector segments 212 may be included when a high degree of interdependence is desired between the nodes 208 and longer or thinner connector segments 212 may be included when a high degree of independence is desired. If desired, the connector segments 212 can be curved to the provide "slack" between the nodes 208, similar to the connector segments 122 described above in connection with membrane 10.
  • the upper layer 204 further includes an axel 216 (or other protrusion) extending from each node 208 toward the lower layer 206. As described in more detail below, the axels 216 are interfitted with corresponding openings 218 in the lower layer 206.
  • each axel 216 includes an elongated cylindrical shaft.
  • each axel 216' generally includes a shaft terminating in a head 222'.
  • the head 222' is an inverted cone having a tapered lower end 224' that facilitates insertion of the axel 216' into the corresponding opening in the lower layer and a substantially flat upper end 226' that resists removal of the axel 216' from the opening in the lower layer.
  • the axel head 222' permits the upper layer 204' and the lower layer to be easily snap-fitted into an interlocking relationship.
  • the head 222' may alternatively include other interlocking shapes.
  • the lower layer 206 provides a support structure for the upper layer 204.
  • the lower layer 206 is optionally elastic and is optionally segregated into nodes 240 corresponding with the upper layer nodes 208.
  • the lower layer 206 is a decoupled, molded elastic membrane similar to membrane 112 described above.
  • the lower layer 206 includes a plurality of square nodes 240 that are interconnected by connector segments 242, 244.
  • the lower layer 206 is oriented in the x direction and includes non-planar connector segments 224 that provide slack in the y direction.
  • each node 240 defines an opening 218 adapted to receive the axel 216 of the corresponding upper layer node 208.
  • a first alternative lower layer 206' is shown in Fig. 12 .
  • the lower layer 206' is oriented in the x direction.
  • the lowcr layer 206' includes square nodes 240' that are interconnected by connector segments 242', 244'.
  • the connector segments 242' link the nodes 240' in the x direction and are essentially planar to provide no slack in the oriented direction.
  • the connector segments 244' link the nodes 240' in the y direction and are arcuate to provide slack in the y direction.
  • a second alternative lower layer 206" is shown in Fig. 13 .
  • This embodiment is essentially identical to lower layer 206', except that the nodes 240" are generally circular. As with lower layer 206', the connector segments 242", 244" of lower layer 206" may provide slack in the y direction, if desired. Although the lower layer is described in connection with various oriented constructions, it is not necessary for the lower layer to be oriented or otherwise decoupled. Similarly, the lower layer 206 need not be segregated into distinct nodes.
  • spring elements are interposed between the upper layer 204 and the lower layer 206.
  • a spring element 250 is disposed between each upper layer node 208 and the corresponding lower layer node 240.
  • spring elements such as a coil spring, may be fitted over each axel 216 disposed between the upper layer 204 and lower layer 206. The characteristics of the separate springs may vary from location to location to provide different support characteristics in different portions of the load bearing surface.
  • the lower layer 306 may include a plurality of integral spring arms 350 that are integrally molded with the lower layer 306.
  • the spring arms 350 are arranged so that a single spring arm 350 is uniquely aligned with each of the upper layer nodes 208.
  • the spring arms 350 are cantilevered and are generally arcuate extending from the lower layer 306 toward the upper layer 204.
  • the upper end 352 of each spring arm 350 is configured to engage the undersurface of the corresponding upper layer node 208.
  • Each spring arm 350 defines an axel opening 318 configured to receive the axel 216 of the corresponding upper layer node 208.
  • the axel opening 318 is smaller than the head of the axel so that the axel snap-fits into the spring arm 350.
  • the arcuate spring arms 350 can be replaced by other cantilevered or otherwise resilient structures, such as arches or domes.
  • the spring elements 450 each include an integral gimbal 460 that facilitates movement of the axel 216 in essentially any direction, thereby giving the upper layer 204 more flexibility.
  • the spring element 450 includes a cantilevered arm 452 extending from the lower layer 406 toward the upper layer 204.
  • the spring arm 450 terminates in an integral gimbal 460.
  • the gimbal 460 generally includes a pivot ring 462 and a mounting ring 464.
  • the pivot ring 462 is connected to the remainder of the spring arm 450 by a pair of flexible bridges 466.
  • the bridges 466 are diametrically opposed to one another on opposite sides of the pivot ring 462.
  • the pivot ring 462 is in turn connected to the mounting ring 464 by a pair of flexible bridges 468.
  • the mounting head bridges 468 are diametrically opposed to one another on opposite sides of the mounting ring 464 and are offset approximately ninety degrees from the pivot ring bridges 466.
  • the pivot ring bridges 466 and mounting ring bridges 468 are sufficiently flexible to permit the mounting ring 464 to pivot in essentially any direction as may be dictated by the load transferred by the axel 216.
  • the characteristics of the gimbal 460 can be tuned to provide the desired support characteristics.
  • the spring elements may be incorporated into the upper layer rather than the lower layer.
  • the spring element may be essentially identical to the spring elements described above.
  • the lower layer can be readily configured to provide localized control over the support characteristics of the load bearing surface.
  • the characteristics of the spring elements may be varied in different regions of the lower layer to provide corresponding variations in the support characteristics in the different regions.
  • the stiffness of select spring elements may be increased or decreased to provide greater or lesser support, as desired.
  • the shape, thickness, length or other characteristics of the spring elements may be varied to provide the desired localized control.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Springs (AREA)
  • Diaphragms And Bellows (AREA)
  • Mattresses And Other Support Structures For Chairs And Beds (AREA)
  • Vibration Prevention Devices (AREA)
  • Manufacture Of Macromolecular Shaped Articles (AREA)

Description

    BACKGROUND OF THE INVENTION
  • The present invention relates to load bearing surfaces, and more particularly to elastomeric load bearing surfaces, such as the seat or back of a chair or bench, or the support surface of a bed, cot or other similar product. In particular, the invention relates to a load bearing surface according to the preamble of claim 1 and to a method for manufacturing a load bearing surface according to the preamble of claim 11. A load bearing surface and a method of this kind are known from US 4,399,574 . GB 2 088 206 A relates to ventilative bedding comprising a plurality of wire coils.
  • There are continuing efforts to develop new and improved load bearing surfaces. In the context of general load bearing surfaces, the primary objectives of these efforts are to obtain a durable and inexpensive load bearing surface. In the context of seating and other body-support applications, it is also important to address comfort issues. For example, with seating, it can be important to provide a surface that is comfortable and docs not create body fatigue over periods of extended use. Given that the load characteristics (e.g. stiffness, resiliency, force/deflection profile) desired in a particular surface will vary from application to application, it is also desirable to have a load bearing surface that is easily tunable for different applications during design and manufacture.
  • It is known to provide molded load bearing surfaces for a wide variety of applications. For example, molded plastic chairs (e.g. lawn chairs) are available from a variety of well known suppliers. Although these molded chairs provide an inexpensive seating option, they do not provide the level of support and comfort available in more expensive load bearing surfaces, such as conventional cushion sets. Rather, they provide an essentially linear force/deflection profile, which gives the typical molded seating surfaces the feel of a drum or a trampoline. In seating and other body-support applications, this may result in an uncomfortable and sometimes ergonomically unacceptable load bearing surface. Further, the ability to tune the characteristics of a conventional molded seat is relatively limited. Different materials and different material thicknesses can be used to provide a limited degree of control over the characteristics of the seat, but this level of control is not sufficient in many applications.
  • There is also an increasing use of elastomeric fabrics in the seating industry. Elastomeric fabrics can provide a comfortable, ventilated seating structure. Elastomeric fabrics are typically manufactured from a complex weave of high tech elastomeric monofilaments and multifilament yarns. The process results in a relatively expensive surface. Although elastomeric fabric surfaces can be quite comfortable in many applications, they typically deflect like a sling when a load is applied. Some ergonomic specialists refer to this type of deflection as "hammocking" and consider it undesirable because it can cause the hips to rotate upward. To minimize hammocking, many suspension seats are stretched quite tightly to reduce the amount of deflection that occurs under load. This can reduce the cushion-like feel of the seat making it feel more like a tightly stretched drum. As a result, elastomeric fabrics may not be ideal in all applications.
  • Accordingly, there remains a need for an elastomeric load bearing surface that is capable of providing non-linear force/deflection profile in response to different loads.
  • SUMMARY OF THE INVENTION
  • The present invention provides an elastomeric load bearing surface having different support characteristics in different directions. In one embodiment, the support characteristics are varied (or decoupled) in directions that are perpendicular to one another.
  • The load bearing surface includes a molded elastomeric membrane that is decoupled by affecting the orientation of the structure of the membrane on a molecular level. In this embodiment, the molded elastomeric membrane may be oriented by compressing or stretching the membrane in one direction to the extent necessary to increase the alignment of the crystallize structure of the elastomer. The orientation process varies the support characteristics of the membrane resulting in a membrane with significant elasticity in the direction of orientation and a low level of creep. The orientation process leaves the membrane with minimal elasticity in the direction perpendicular to the oriented direction.
  • In one embodiment, the molded elastomeric membrane includes mechanical structure that affects the support and load bearing characteristics of the membrane. In this embodiment, the membrane may include without limitation slits, channels, undulations or other integral elements that provide "slack" in one direction. If desired, the membrane may be oriented and include mechanical decoupling structure.
  • In another embodiment, the membrane is segregated into a plurality of nodes that provide a degree of independence from one location on the membrane to another. In one embodiment, the membrane defines a plurality of interconnected geometric shapes. For example, the membrane may include a plurality of square or triangular nodes that are interconnected by integral connector segments. The characteristics of the connector segments may be varied to control the support characteristics of the membrane. For example, the membrane may include non-planar connector segments that can flex or otherwise deform under load to provide the membrane with "slack."
  • The present invention also provides a method of manufacturing a load bearing surface from an elastomeric material. The method generally includes the steps of (a) molding an elastomeric membrane and (b) orienting the elastomeric membrane in one direction by stretching the elastomeric membrane in that direction or by compressing the elastomeric membrane in such a way as to cause it to flow in that direction. The elastomeric membrane is stretched or compressed to a point where there is an increase in the alignment of the crystalline structure of the elastomeric material in the oriented direction. In one embodiment, the method further includes the step of molding the elastomeric membrane with a structure that mechanically decouples the membrane in a direction different from that in which the membrane is oriented. This decoupled direction may be perpendicular to the oriented direction.
  • In one embodiment, the membrane is compressed by the steps of (a) constraining the membrane on all sides except those sides corresponding with the desired direction of orientation and (b) applying a compression force to the membrane such that the material of the membrane flows in the unconstrained direction to increase the alignment of the crystalline structure of the membrane in the direction of flow.
  • The present invention provides a strong, yet flexible load bearing surface. The elastomeric load bearing surfaces are relatively inexpensive to manufacture, and provide a light weight surface that can be ventilated to inhibit heat retention. The decoupled elastomeric material exhibits support characteristics that are particularly well suited for use in seating applications because it provides different degrees of elasticity and support in different directions. For example, the decoupled elastomeric material can provide a seating structure with elasticity in the left to right direction, but not in the front to back direction. Further, by increasing the alignment of the crystalline structure of the elastomeric material, the level of creep in the membrane can be dramatically reduced.
  • These and other objects, advantages, and features of the invention will be readily understood and appreciated by reference to the detailed description of the preferred embodiment and the drawings.
  • BRIEF DESCRIPTION OF THE DRAWINGS
    • Fig. 1 is a perspective view of a load bearing surface in accordance with one embodiment of the present invention.
    • Fig. 2A a perspective view of an alternative load bearing surface having a plurality of nodes.
    • Fig. 2B is an enlarged perspective view of a portion of the load bearing surface of Fig. 2A.
    • Fig. 3A is a top plan view of a molded elastomeric membrane prior to orientation.
    • Fig. 3B is a top plan view of the molded elastomeric membrane during orientation.
    • Fig. 3C is a top plan view of the molded elastomeric membrane after orientation.
    • Fig. 4 is a sectional view of the molded elastomeric membrane taken along line 4-4 of Fig. 3C.
    • Fig. 5A is a perspective view of a first alternative load bearing surface.
    • Fig. 5B is a sectional view of the first alternative load bearing surface taken along line 5B-5B.
    • Fig. 6A is a perspective view of a second alternative load bearing surface.
    • Fig. 6B is a sectional view of the second alternative load bearing surface taken along line 6B-6B.
    • Fig. 7A is a perspective view of a third alternative load bearing surface.
    • Fig. 7B is a sectional view of the third alternative load bearing surface taken along line 7B-7B.
    • Fig. 8A is an enlarged cross-sectional view of a portion of an elastomeric membrane having an integral edge.
    • Fig. 8B is a cross-sectional enlarged view of a portion of an elastomeric membrane having a first alternative integral edge.
    • Fig. 8C is an enlarged cross-sectional view of a portion of an elastomeric membrane having a second alternative integral edge.
    • Fig. 9 is a perspective view of a two layer load bearing surface in accordance with one embodiment of the present invention.
    • Fig. 10 is an enlarged perspective view of a portion of the load bearing surface of Fig. 9.
    • Fig. 11 is an exploded of the load bearing surface showing a single spring and single node and a portion of the lower layer
    • Fig. 12 is a top plan view of an alternative lower layer.
    • Fig. 13 is a top plan view of a second alternative lower layer.
    • Fig. 14 is a perspective view of an alternative lower layer with an integral spring element.
    • Fig. 15 is a perspective view of a second alternative lower layer with an integral spring element.
    • Fig. 16 is a perspective view of an alternative top layer with triangular nodes.
    • Fig. 17 is a perspective view of a single node of the alternative top layer of Fig. 16.
    DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
  • A load bearing surface 10 according to one embodiment of the present invention is shown in Fig. 1. The load bearing surface 10 shown in Fig. 1 is a molded membrane that may be suspended from a support structure, such a chair seat frame (not shown). The load bearing surface 10 includes support characteristics that differ in different directions. For example, the load bearing surface may provide significant elastic support in the x direction while providing relatively little support in the y direction. This "decoupling" of the support characteristics of the load bearing surface provides a high degree of comfort. By way of disclosure, the present invention is described in connection with various alternative embodiments intended primarily for use in seating applications. The present invention is not, however, limited to use in seating applications, but may also be incorporated into other load bearing applications. The support characteristics of the molded membrane are highly adjustable, thereby permitting the load bearing surface 10 to be tailored to support a variety of loads in a variety of different applications.
  • In the embodiment of Fig. 1, the load bearing surface 10 includes a molded elastomeric membrane 12. In the illustrated embodiment, the membrane 12 is molded from a thermoplastic polyether ester elastomer block copolymer. One suitable material of this type is available from DuPont under the Hytrel® trademark. A variety of alternative elastomers may be suitable for use in the present invention. The thickness of the molded membrane 12 will vary from application to application depending primarily on the anticipated load, but the support portion of the membrane may have an average thickness prior to any desired orienting of approximately 20-40 mm in standard seating applications. In one embodiment, the molded membrane 12 is oriented in one direction (i.e. the x direction) to provide creep resistance and elasticity in the direction of orientation. The membrane 12 is oriented by increasing the alignment of the crystalline structure of the elastomeric membrane on a molecular level so that its support and other load bearing characteristics are altered. Typically, the membrane with be oriented to such a degree that the oriented membrane 12 has materially different load bearing characteristics in the oriented direction than in other directions. One method for orienting the membrane 12 is through stretching. The amount of stretch required to obtain the desired alignment will vary from application to application, but in most applications the desired degree of alignment will occur when the membrane is stretched to roughly two times its original dimension. Although the elastomeric membrane 12 may be oriented by stretching the membrane, it may be possible in some application to orient the membrane 12 using other processes. For example, it may be possible to orient certain materials by hammering or other forms of compression, rather than stretching the membrane 12. It should be noted that many elastomeric materials, including molded Hytrel®, have essentially no elasticity and are susceptible to a high degree of creep when in a molded form. The orientation process of the present invention causes a significant change in the properties of the elastomeric material. For example, orientation of the membrane 12 increases the elasticity of the material and decreases its inherent susceptibility to creep. The elastomeric membrane 12 of Fig. 1 also includes a plurality of undulations 14 that provide "slack" in the direction perpendicular to the direction of orientation (i.e. the y direction). When a load is applied to the membrane 12, the undulations 14 can undergo a "flattening" that permits the membrane 12 to expand in the y direction. The undulations 14 and other mechanical decoupling structures are described in more detail below.
  • The membrane 12 of Fig. 1 also includes an integral edge 16 that may be mounted directly to the desired support structure (not shown), such as the seat frame of a chair. In the illustrated embodiment, the edge 16 extends around the periphery of the membrane 12 and is significantly thicker than the remainder of the membrane 12. The edge 16 may include integral snap or other attachment features (not shown) that facilitate attachment of the membrane 12 to the support structure. Alternatively, the edge 16 may be attached using fasteners (not shown), such as screws or bolts. The edge 16 does not necessarily extend entirely around the membrane 12, but may instead include one or more segments located at different locations around the periphery. For example, an edge segment may be located in each corner of a rectangular membrane (not shown). The edge 16 is also not necessarily located on the periphery of the membrane 12. In some application, it may be desirable to have one or more edge segments located within the interior of the membrane 12. For example, in an elongated surface, an edge segment may be included in the central interior of the membrane to provide a central mounting location (not shown). Three alternative edge constructions are shown in Figs. 8A-C. Fig. 8A shows an edge 16' having holes 17' to facilitate attachment of the edge 16' to a support structure (not shown). For example, fasteners (not shown) may pass through the holes 17'. Alternatively, the holes 17' may be fitted over attachment structure on the support structure (not shown), such as post. Fig. 8B shows an edge 16" that is substantially circular in cross section. Fig. 8C shows an edge 16''' that is substantially square in cross section.
  • As noted above, the elastomeric membrane 12 is molded using conventional techniques and apparatus. For example, the elastomeric membrane 12 may be injection molded using a conventional injection molding apparatus (not shown) having a die that is configured to provide a membrane with the desired shape and features. In this embodiment, the elastomeric membrane 12 is manufactured by injecting the desired material into the die cavity. The die is designed to provide a molded blank (See Fig. 3A) that will take on the desired shape once any desired orientation have taken place. For example, the dies are configured to form a part that will have the desired shape and dimensions after the orientation step is complete. After molded, the molded membrane may be stretched or otherwise oriented in one direction (See Fig. 3B). If orientation is achieved through stretching, the precise amount of stretch to be applied to a given membrane will depend on the configuration of the membrane and the desired support characteristics. In many applications, it will be necessary to stretch the membrane to at least twice it original length to achieve the desired alignment. The membrane may be stretched using conventional techniques and apparatus. As a result of the increase in alignment of the crystalline structure, the membrane 12 will not fully return to its original length after being released from the stretching equipment. Rather, the oriented membrane 12 will be elongated a certain portion of the stretched distance, with the precise amount of elongation being dependent in large part on the material characteristics of the membrane material (See Fig. 3C). Once any desired orientation has taken place, the membrane 12 can be mounted directly to the support structure using essentially any mounting technique. For example, the edge 16 of the membrane (shown in Fig. 4) can be fastened to a support structure by screws or other fasteners. As an alternative to stretching, the membrane 12 may be oriented by compression. In one embodiment for orienting by compression, the membrane 12 is placed in a die or other structure (not shown) that constrains the membrane 12 on all sides other than at least one side that corresponds with the desired direction of orientation. Opposed sides may be unconstrained to permit the material of the membrane 12 to flow from both sides along the direction of orientation. Alternatively, only a single side may be unconstrained, thereby limiting material flow to a single side. A compressive force is then applied to the membrane 12. For example, a press can be used to compress the membrane 12 within the die. Sufficient compressive force is applied so that the material begins to flow in the unconstrained direction. This in effect causes the membrane 12 to extend and its crystalline structure to become increasingly aligned in the direction of orientation. The amount of force applied to the membrane 12 may vary from application depending on the desired degree of alignment or orientation. Although described in connection with orientation of the entire elastomeric membrane 12, in some application it is not necessary to orient the entire membrane 12. Rather, in some application, it may be desirable to orient only select portions of the membrane. For example, in some applications it may be desirable to orient only select peripheral portions of the membrane. When desirable, this may be achieved by applying localized stretching or localized compression of the membrane.
  • The use of a molded membrane in the present invention provides the ability to easily create textures on the membrane, provide the membrane with essentially any desired contour and vary the thickness of the membrane in different locations. Although not shown, the upper surface of the membrane may be smooth or may be textured to provide the appearance of leather, fabric or other desired textures. Similarly, the upper surface of the membrane may be provided with essentially any conceivable design elements (not shown), such as tiny bumps, corrugations, perforations or a spider web pattern. The use of contours and varying thicknesses across the membrane 12 permits localized control over the support characteristics of the membrane 12. For example, the membrane 12 may be thicker in regions where increased support is desired.
  • Various alternative embodiments of the present invention will be described in the following paragraphs. In each of these alternative embodiments, the elastomeric membrane may be oriented in one direction to reduce creep and provide the membrane with a desired level of elasticity in the direction of orientation.
  • An alternative embodiment is shown in Fig. 5A-B. In this embodiment, the membrane 12' defines a plurality of slits or apertures that decouple the stiffness of the membrane in the x and y directions. More specifically, the membrane 12' defines a plurality of apertures 26' that permit a specific amount of extension of the membrane in the desired direction (i.e. the y direction) without significant stretching of the membrane 12'. The apertures 26' may be elongated as shown in Fig. 5A. As shown, the apertures 26' may by staggered across the surface of the membrane 12' with the precise shape, number, location and size of the apertures 26' being dictated primarily by the desired support characteristics. As shown in Fig. 5B, the membrane 12' may be molded with a bead 27' around each aperture 26' to reduce the possibility of tearing. As noted above, the membrane 12' may be oriented in the x direction as described above in connection with membrane 12.
  • A second alternative embodiment is shown in Figs. 6A-B. In this embodiment, the membrane 12" includes undulating variations 26" that decouple the stiffness of the membrane 12" by providing "slack" in one direction (e.g. the y direction). As shown in Fig. 6B, the undulating variations 26" may be sinusoidal when viewed in cross-section. Alternatively, the undulating variations 26" may resemble an accordion or pleated configuration when view in cross-section. The undulations may follow essentially any contour that varies in the z direction. In this embodiment, the undulations 26" are arranged parallel to one another. As a result, the undulations 26" cooperate to provide slack in essentially one direction. The undulations 26" may, however, be in a non-parallel arrangement when appropriate to provide the desired support characteristics. The number, size, shape and location of the undulations 26" can be tuned to provide control over the support characteristics of the membrane 12".
  • A third alternative embodiment is shown in Fig. 7A-B. In this embodiment, the membrane 10''' includes a plurality of ribs 26''' extending at least partially across the membrane 12"'. In one embodiment, the membrane 12"' includes a plurality of parallel ribs 26'''. The ribs 26"' provide the membrane 12''' with additional material that reduces the force required to stretch the membrane 12''' in the direction perpendicular to the ribs 26"' (i.e. the y direction), while at the same time having little effect on the force required to stretch the membrane 12''' in the direction parallel to the ribs (i.e. the x direction). The number, size, shape and location of the ribs 26''' can be tuned to provide control over the support characteristics of the membrane 12"'.
  • The load bearing surface may optionally be divided into a plurality of nodes. The molded elastomeric membrane 112 shown in Figs. 2A-B includes a plurality nodes 118 interconnected by a plurality of connector segments 120, 122. As perhaps best shown in Fig. 2B, the nodes 118 and connector segments 120, 122 are integrally formed as a single molded part. In the embodiment of Figs. 2A-B, the membrane 112 includes a plurality of substantially square, equal-sized, regularly-spaced nodes 118. The nodes 118 need not, however, be of equal-size or be regularly-spaced. Rather, the nodes 118 may vary in size, shape, spacing or other characteristics in different regions of the membrane 112 to provide localized control over the support characteristics of the membrane 112 in the different regions. Although the nodes 118 of this embodiment are substantially square, they may vary in shape from application to application. For example, circular, triangular, rectangular or irregular shapes nodes may be desired in certain applications. The illustrated nodes 118 have a generally planar upper surface 124, but the upper surface 124 may be contoured. For example, the nodes 118 may have a convex upper surface (not shown). It should also be recognized that the spaces 126 defined between the nodes 118 and the connector segments 120, 122 provide a ventilated membrane 112. The size, shape and configuration of the spaces 126 can be tailored to provide the desired balance between ventilation and support characteristics.
  • As noted above, the nodes 118 are interconnected by a plurality of connector segments 120, 122 (See Fig. 2B). The support characteristics of the membrane 112 are affected by the number, size, shape and other characteristics of the connector segments 120, 122. In this embodiment, the membrane 110 configured to provide elastic support along one direction. Accordingly, the connector segments 120 joining the nodes 118 in the oriented direction x are substantially planar. As a result, the elastomeric membrane 112 undergoes a stretching action in the direction of orientation when a load is applied. In this embodiment, the membrane 112 is configured to have minimal elastic response in the y direction (i.e. the direction perpendicular to the oriented direction). Accordingly, the connector segments 122 joining the nodes 118 in the y direction are generally non-planar following a somewhat U-shaped arc. As a result, the connector segments 122 provide the membrane with "slack" in the direction perpendicular to the oriented direction. Under load, the non-planar connectors 122 undergo a bending action that essentially flats the connectors taking the "slack" out of the membrane 112. This permits the membrane 112 to undergo a certain amount of expansion in the direction of the slack without stretching of the membrane 112. The amount of load required to achieve this expansion can be built into the membrane 112 by tuning the design and configuration of the connector segments 120, 122. Although the precise force required to achieve the bending action will vary, the bending action generally provides significantly less resistance to the expansion of the membrane 112 and less elastic return than would normally result from a stretching action. As a result, the membrane 112 provides elastic support primarily in the direction of orientation.
  • In the embodiment of Figs. 9-11, the load bearing surface 200 includes an upper layer 204 having a plurality of loosely connected nodes 208, a lower layer 206 that interfaces with and supports the upper layer 204 and a plurality of spring elements 250 interposed between the upper layer 204 and the lower layer 206. In one embodiment, the upper layer 204 includes a plurality of interconnected nodes 208. The upper layer 204 may be a single molded sheet formed with integral connector segments 212 that interconnect adjacent nodes 208. In the embodiment of Figs. 9-11, the nodes 208 are square. But, the nodes 208 may be of other shapes. For example, in the alternative embodiment of Figs. 16-17, the nodes 208' are triangular. The characteristics of the connector segments 212 are selected to provide the desired level of interdependence between adjacent nodes 208. For example, relatively short, thick connector segments 212 may be included when a high degree of interdependence is desired between the nodes 208 and longer or thinner connector segments 212 may be included when a high degree of independence is desired. If desired, the connector segments 212 can be curved to the provide "slack" between the nodes 208, similar to the connector segments 122 described above in connection with membrane 10. In the illustrated embodiment, the upper layer 204 further includes an axel 216 (or other protrusion) extending from each node 208 toward the lower layer 206. As described in more detail below, the axels 216 are interfitted with corresponding openings 218 in the lower layer 206. The interfitted relationship permits the lower layer 206 to shepherd movement of the upper layer 204. The axels 216 may have various shapes. But, in the embodiment of Figs. 9-11, each axel 216 includes an elongated cylindrical shaft. In the alternative embodiment, shown in Figs. 16 and 17, each axel 216' generally includes a shaft terminating in a head 222'. The head 222' is an inverted cone having a tapered lower end 224' that facilitates insertion of the axel 216' into the corresponding opening in the lower layer and a substantially flat upper end 226' that resists removal of the axel 216' from the opening in the lower layer. The axel head 222' permits the upper layer 204' and the lower layer to be easily snap-fitted into an interlocking relationship. The head 222' may alternatively include other interlocking shapes.
  • The lower layer 206 provides a support structure for the upper layer 204. The lower layer 206 is optionally elastic and is optionally segregated into nodes 240 corresponding with the upper layer nodes 208. In the embodiment of Figs. 9-11, the lower layer 206 is a decoupled, molded elastic membrane similar to membrane 112 described above. The lower layer 206 includes a plurality of square nodes 240 that are interconnected by connector segments 242, 244. As with membrane 112, the lower layer 206 is oriented in the x direction and includes non-planar connector segments 224 that provide slack in the y direction. Unlike membrane 112, however, each node 240 defines an opening 218 adapted to receive the axel 216 of the corresponding upper layer node 208.
  • The configuration of the nodes 240 and connector segments 242, 244 may vary from application to application. A first alternative lower layer 206' is shown in Fig. 12. In this embodiment, the lower layer 206' is oriented in the x direction. The lowcr layer 206' includes square nodes 240' that are interconnected by connector segments 242', 244'. The connector segments 242' link the nodes 240' in the x direction and are essentially planar to provide no slack in the oriented direction. The connector segments 244' link the nodes 240' in the y direction and are arcuate to provide slack in the y direction. A second alternative lower layer 206" is shown in Fig. 13. This embodiment is essentially identical to lower layer 206', except that the nodes 240" are generally circular. As with lower layer 206', the connector segments 242", 244" of lower layer 206" may provide slack in the y direction, if desired. Although the lower layer is described in connection with various oriented constructions, it is not necessary for the lower layer to be oriented or otherwise decoupled. Similarly, the lower layer 206 need not be segregated into distinct nodes.
  • As noted above, spring elements are interposed between the upper layer 204 and the lower layer 206. Preferably (but not necessarily), a spring element 250 is disposed between each upper layer node 208 and the corresponding lower layer node 240. As shown in Figs. 9-11, spring elements, such as a coil spring, may be fitted over each axel 216 disposed between the upper layer 204 and lower layer 206. The characteristics of the separate springs may vary from location to location to provide different support characteristics in different portions of the load bearing surface.
  • The spring elements may alternatively be integrated into the lower layer. As show in Fig. 14, the lower layer 306 may include a plurality of integral spring arms 350 that are integrally molded with the lower layer 306. The spring arms 350 are arranged so that a single spring arm 350 is uniquely aligned with each of the upper layer nodes 208. The spring arms 350 are cantilevered and are generally arcuate extending from the lower layer 306 toward the upper layer 204. The upper end 352 of each spring arm 350 is configured to engage the undersurface of the corresponding upper layer node 208. Each spring arm 350 defines an axel opening 318 configured to receive the axel 216 of the corresponding upper layer node 208. In this embodiment, the axel opening 318 is smaller than the head of the axel so that the axel snap-fits into the spring arm 350. The arcuate spring arms 350 can be replaced by other cantilevered or otherwise resilient structures, such as arches or domes.
  • An alternative integral spring construction is shown in Fig. 15. In this embodiment, the spring elements 450 each include an integral gimbal 460 that facilitates movement of the axel 216 in essentially any direction, thereby giving the upper layer 204 more flexibility. The spring element 450 includes a cantilevered arm 452 extending from the lower layer 406 toward the upper layer 204. The spring arm 450 terminates in an integral gimbal 460. The gimbal 460 generally includes a pivot ring 462 and a mounting ring 464. The pivot ring 462 is connected to the remainder of the spring arm 450 by a pair of flexible bridges 466. The bridges 466 are diametrically opposed to one another on opposite sides of the pivot ring 462. The pivot ring 462 is in turn connected to the mounting ring 464 by a pair of flexible bridges 468. The mounting head bridges 468 are diametrically opposed to one another on opposite sides of the mounting ring 464 and are offset approximately ninety degrees from the pivot ring bridges 466. In use, the pivot ring bridges 466 and mounting ring bridges 468 are sufficiently flexible to permit the mounting ring 464 to pivot in essentially any direction as may be dictated by the load transferred by the axel 216. The characteristics of the gimbal 460 can be tuned to provide the desired support characteristics.
  • In yet another alternative embodiment, the spring elements may be incorporated into the upper layer rather than the lower layer. In this embodiment, the spring element may be essentially identical to the spring elements described above.
  • The lower layer can be readily configured to provide localized control over the support characteristics of the load bearing surface. If desired, the characteristics of the spring elements may be varied in different regions of the lower layer to provide corresponding variations in the support characteristics in the different regions. For example, the stiffness of select spring elements may be increased or decreased to provide greater or lesser support, as desired. The shape, thickness, length or other characteristics of the spring elements may be varied to provide the desired localized control.

Claims (15)

  1. A load bearing surface (10; 10"') comprising a molded elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406), said membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) being decoupled between a first direction and a second direction, whereby said membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) provides different load bearing characteristics in said first direction and said second direction,
    characterized in that
    said membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) includes a crystalline structure having a greater degree of alignment in said first direction than in other directions.
  2. The surface of claim 1 wherein said first direction is oriented approximately ninety degrees from said second direction.
  3. The surface of claim 1 or 2 wherein said membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) includes a mechanical structure (14; 26'; 26"; 26"') decoupling said membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) in said second direction.
  4. The surface of one of the preceding claims wherein said membrane (12; 12'; 12"; 12"') includes an integral edge (16; 16'; 16"; 16"') adapted to permit mounting of said membrane (12; 12'; 12"; 12"') to a support structure.
  5. The surface of claim 3 wherein said mechanical structure includes a plurality of contours integrally formed with said membrane.
  6. The surface of claim 3 wherein said mechanical structure includes a plurality of channels integrally formed with said membrane, said channels extending in substantially said first direction.
  7. The surface of claim 3 wherein said mechanical structure includes a plurality of apertures (26') defined in said membrane (12'), said apertures (26') being elongated in substantially said first direction.
  8. The surface of claim 3 wherein said mechanical structure includes a plurality of ribs (26"') integrally formed with said membrane (12"'), said ribs (26"') extending in substantially said first direction.
  9. The surface of claim 3 wherein said mechanical structure includes a plurality of sinusoidal variations (26") integrally formed with said membrane (12"), said variations (26") extending in substantially said first direction.
  10. The surface of claim 1 wherein said membrane (112; 206; 206'; 206"; 306; 406) defines a plurality of nodes (118; 240; 240') interconnected by a plurality of connectors (120, 122; 242, 244; 242', 244'; 242", 244"), said connectors (120; 242; 242'; 242") extending in said first direction having different physical characteristics than said connectors (122; 244; 244'; 244") extending in said second direction, whereby said membrane (112; 206; 206'; 206"; 306; 406) is decoupled at least in part by differences in said physical characteristics of said plurality of connectors (120, 122; 242, 244; 242', 244'; 242", 244").
  11. A method for manufacturing a load bearing surface, comprising the step of:
    molding an elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406);
    characterized by the step of:
    orienting at least a portion of the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) in only one direction until the crystalline structure of the membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) becomes sufficiently aligned in the one direction to provide the portion of the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) with load bearing characteristics in the one direction that are different from other directions.
  12. The method of claim 11 wherein said orienting step is further defined as stretching at least a portion of the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) in the one direction to at least approximately twice the original dimension of the portion of the membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406).
  13. The method of claim 11 wherein said orienting step is further defined as:
    constraining at least a portion of the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) on all sides except at least one unconstrained side corresponding with the one direction; compressing the portion of the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) until the material of the portion of the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) flows outwardly along at the unconstrained side in the one direction.
  14. The method of one of claims 11 to 13 further including the steps of: molding the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) with an integral edge (16; 16'; 16"; 16"'); and attaching the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) to a support structure by the edge (16; 16'; 16"; 16"').
  15. The method of one of claims 11 to 14 wherein the elastomeric membrane (12; 12'; 12"; 12"'; 112; 206; 206'; 206"; 306; 406) is manufactured from a thermoplastic polyether ester elastomer block copolymer.
EP05012021A 2004-06-17 2005-06-03 Load bearing surface Active EP1607028B1 (en)

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US58064804P 2004-06-17 2004-06-17
US580648P 2004-06-17
US112345 2005-04-22
US11/112,345 US7441758B2 (en) 2004-06-17 2005-04-22 Load bearing surface
US11/423,220 US20060286359A1 (en) 2004-06-17 2006-06-09 Load bearing surface
US11/423,540 US9215933B2 (en) 2004-06-17 2006-06-12 Load bearing surface

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EP10167976.9 Division-Into 2010-06-30

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EP1607028A2 EP1607028A2 (en) 2005-12-21
EP1607028A3 EP1607028A3 (en) 2006-02-08
EP1607028B1 true EP1607028B1 (en) 2011-02-02

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EP10167976A Active EP2238868B1 (en) 2004-06-17 2005-06-03 Load bearing surface
EP06795779.5A Active EP2026680B1 (en) 2004-06-17 2006-08-25 Load bearing surface

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US (6) US7441758B2 (en)
EP (3) EP1607028B1 (en)
JP (2) JP4504259B2 (en)
KR (1) KR20090027621A (en)
CN (3) CN101543357B (en)
WO (1) WO2007144703A1 (en)

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EP1607028A3 (en) 2006-02-08
US20060267258A1 (en) 2006-11-30
JP2006000646A (en) 2006-01-05
CN101437425A (en) 2009-05-20
CN101543357B (en) 2014-04-09
JP4504259B2 (en) 2010-07-14
WO2007144703A1 (en) 2007-12-21
CN101543357A (en) 2009-09-30
KR20090027621A (en) 2009-03-17
EP2238868A1 (en) 2010-10-13
CN1792298A (en) 2006-06-28
US20050279591A1 (en) 2005-12-22
US20090020931A1 (en) 2009-01-22
US7441758B2 (en) 2008-10-28
CN100551301C (en) 2009-10-21
US9173496B2 (en) 2015-11-03
US9215933B2 (en) 2015-12-22
EP1607028A2 (en) 2005-12-21
JP2009165879A (en) 2009-07-30
US20060286359A1 (en) 2006-12-21
EP2026680A1 (en) 2009-02-25
US20160214310A1 (en) 2016-07-28
US8534648B2 (en) 2013-09-17
EP2026680B1 (en) 2019-06-05
US10226893B2 (en) 2019-03-12
EP2238868B1 (en) 2012-08-22
JP5186622B2 (en) 2013-04-17
US20090020932A1 (en) 2009-01-22
CN101437425B (en) 2012-07-18

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